The half-wave maps equation on T: Global well-posedness in H1/2 and almost periodicity

Abstract

We consider the half-wave maps equation ∂t u = u × |D| u for u : R × T S2, where T=R/2 π Z is the one-dimensional torus and S2 ⊂ R3 denotes the unit sphere. By extension from rational initial data, we construct a unique and continuous flow map for data in the critical energy space H1/2(T; S2). Moreover, we show almost periodicity in time of these solutions. For the dense subset of rational initial data, we establish quasi-periodicity in time and a-priori bounds on \| u(t) \|Hs(T) for any s >0. Our analysis relies crucially on an explicit formula arising from the Lax pair structure acting on a Hardy space of vector-valued holomorphic functions on the unit disk. As a central ingredient, we develop a general stability principle for explicit formulae associated with completely integrable PDEs possessing a Lax pair structure on Hardy spaces, including the Benjamin--Ono equation, Calogero--Sutherland DNLS, and the half-wave-maps equation posed on T. Our results extend to the matrix-valued half-wave maps equation ∂t U = -i2 [ U, |D| U ] with target manifold given by the complex Grassmannians Grk(Cd), thereby generalizing the special case S2 CP1 Gr1(C2). In a companion work, we prove global well-posedness for the half-wave maps equation posed on R in the scaling-critical energy space H1/2, by establishing a stability principle for explicit formulae on Hardy spaces in the complex half-plane C+.